Field-Effect Control of Metallic Superconducting Systems

TL;DR

This paper reviews experimental evidence of electric field control over superconducting properties in metallic systems, challenging traditional theories and suggesting new device applications in quantum and classical computing.

Contribution

It compiles and analyzes experimental results demonstrating field-effect modulation of superconductivity in metals, revealing phenomena unexplained by conventional theories.

Findings

Electric fields can modulate supercurrent without changing critical temperature or normal resistance.

Superconducting phase can be controlled via electric fields in Josephson devices.

Proposed devices could revolutionize superconducting quantum and classical computation.

Abstract

Despite metals are believed to be insensitive to field-effect and conventional Bardeen-Cooper-Schrieffer (BCS) theories predict the electric field to be ineffective on conventional superconductors, a number of gating experiments showed the possibility of modulating the conductivity of metallic thin films and the critical temperature of conventional superconductors. All these experimental features have been explained by simple charge accumulation/depletion. In 2018, electric field control of supercurrent in conventional metallic superconductors has been demonstrated in a range of electric fields where the induced variation of charge carrier concentration in metals is negligibly small. In fact, no changes of normal state resistance and superconducting critical temperature were reported. Here, we review the experimental results obtained in the realization of field-effect metallic superconducting devices exploiting this unexplained phenomenon. We will start by presenting the seminal results on superconducting BCS wires and nano-constriction Josephson junctions (Dayem bridges) made of different materials, such as titanium, aluminum and vanadium. Then, we show the mastering of the Josephson supercurrent in superconductor-normal metal-superconductor proximity transistors suggesting that the presence of induced superconducting correlations are enough to see this unconventional field-effect. Later, we present the control of the interference pattern in a superconducting quantum interference device indicating the coupling of the electric field with thesuperconducting phase. Among the possible applications of the presented phenomenology, we conclude this review by proposing some devices that may represent a breakthrough in superconducting quantum and classical computation.